Project description: Not available

Project description:Background and Purpose: Genome-wide association studies significantly link intracranial aneurysm (IA) to single-nucleotide polymorphisms (SNPs) in six genomic loci. To gain insight into the relevance of these IA associated SNPs, we aimed to identify regulatory regions and analyze overall gene expression in the human circle of Willis (CoW), on which these aneurysms develop. Methods: We performed chromatin immunoprecipitation and sequencing for histone modifications H3K4me1 and H3K27ac to identify regulatory regions, including distal enhancers and active promoters, in post mortem specimens of the human CoW. These experiments were complemented with RNA sequencing on the same specimens. We determined whether these regulatory regions overlap with IA associated SNPs, using computational methods. By combining our results with publicly available data, we investigated the effect of IA associated SNPs on the newly identified regulatory regions and linked them to potential target genes. Results: We find that IA associated SNPs are significantly enriched in CoW regulatory regions. Some of the IA associated SNPs that overlap with a regulatory region are likely to alter transcription factor binding, and in proximity to these regulatory regions are 102 genes that are expressed in the CoW. In addition, gene expression in the CoW is enriched for genes related to cell adhesion and the extracellular matrix. Conclusions: CoW regulatory regions link IA associated SNPs to genes with a potential role in the development of IAs. Our data refine previous predictions on SNPs associated with IA and provide a substantial resource from which candidates for follow-up studies can be prioritized.

Project description:Genetic changes that help explain the differences between two individuals might create or disrupt sites complementary to microRNAs (miRNAs), but the extent to which such polymorphic sites influence miRNA-mediated repression is unknown. Here, we describe a method to measure mRNA allelic imbalances associated with a regulatory site found in mRNA transcribed from one allele but not found in that transcribed from the other. Applying this method, called allelic imbalance sequencing, to sites for three miRNAs (miR-1, miR-133 and miR-122) provided quantitative measurements of repression in vivo without altering either the miRNAs or their targets. A substantial fraction of polymorphic sites mediated repression in tissues that expressed the cognate miRNA, and downregulation was correlated with site type and site context. Extrapolating these results to the other broadly conserved miRNAs suggests that when comparing two mouse strains (or two human individuals), polymorphic miRNA sites cause expression of many genes (often hundreds) to differ. There are four distinct samples (pool1-4), each of which is a pool of ~60 distinct PCR or RT-PCR products. The samples were loaded into different segments of the same pyrosequencing plate. Three sequencing runs (run1-3) were performed for each sample pool. Any amplicons of the four pools are for miR-1, miR-122, miR-133 or control sites. To control for allele-specific PCR bias, genomic DNA was also used as a template for generating amplicons.

Project description: Not available

Project description:Genetic changes that help explain the differences between two individuals might create or disrupt sites complementary to microRNAs (miRNAs), but the extent to which such polymorphic sites influence miRNA-mediated repression is unknown. Here, we describe a method to measure mRNA allelic imbalances associated with a regulatory site found in mRNA transcribed from one allele but not found in that transcribed from the other. Applying this method, called allelic imbalance sequencing, to sites for three miRNAs (miR-1, miR-133 and miR-122) provided quantitative measurements of repression in vivo without altering either the miRNAs or their targets. A substantial fraction of polymorphic sites mediated repression in tissues that expressed the cognate miRNA, and downregulation was correlated with site type and site context. Extrapolating these results to the other broadly conserved miRNAs suggests that when comparing two mouse strains (or two human individuals), polymorphic miRNA sites cause expression of many genes (often hundreds) to differ.

Project description: Not available

Project description: Not available

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Project description: Not available

Project description: Not available